subroutine sync65(dat,jz,DFTolerance,NFreeze,NAFC,MouseDF, + dtx,dfx,snrx,snrsync,ccfblue,ccfred,flip,width,ftrack) C Synhronizes JT65 data, finding the best-fit DT and DF. C NB: at this stage, submodes ABC are processed in the same way. parameter (NP2=60*11025) !Size of data array parameter (NFFTMAX=2048) !Max length of FFTs parameter (NHMAX=NFFTMAX/2) !Max length of power spectra parameter (NSMAX=320) !Max number of half-symbol steps integer DFTolerance !Range of DF search real dat(jz) real psavg(NHMAX) !Average spectrum of whole record real s2(NHMAX,NSMAX) !2d spectrum, stepped by half-symbols real ccfblue(-5:540) !CCF with pseudorandom sequence real ccfred(-224:224) !Peak of ccfblue, as function of freq real tmp(450) integer itry(100) real ftrack(126) save C Do FFTs of symbol length, stepped by half symbols. Note that we have C already downsampled the data by factor of 2. nsym=126 nfft=2048 nsteps=2*jz/nfft - 1 nh=nfft/2 df=0.5*11025.0/nfft C Compute power spectrum for each step and get average call zero(psavg,nh) do j=1,nsteps k=(j-1)*nh + 1 call limit(dat(k),nfft) call ps(dat(k),nfft,s2(1,j)) call add(psavg,s2(1,j),psavg,nh) enddo call flat1(psavg,s2,nh,nsteps,NHMAX,NSMAX) !Flatten the spectra C Find the best frequency channel for CCF fa= 670.46 fb=1870.46 if(NFreeze.eq.1) then fa=max( 670.46,1270.46+MouseDF-DFTolerance) fb=min(1870.46,1270.46+MouseDF+DFTolerance) endif ia=fa/df ib=fb/df i0=nint(1270.46/df) ired0=ia-i0 ired1=ib-i0 lag1=-5 lag2=59 syncbest=-1.e30 syncbest2=-1.e30 call zero(ccfred,449) do i=ia,ib call xcor(s2,i,nsteps,nsym,lag1,lag2, + ccfblue,ccf0,lagpk0,flip,0.0) ccfred(i-i0)=ccf0 C Find rms of the CCF, without the main peak call slope(ccfblue(lag1),lag2-lag1+1,lagpk0-lag1+1.0) sync=abs(ccfblue(lagpk0)) ppmax=psavg(i)-1.0 C Find the best sync value if(sync.gt.syncbest2) then ipk2=i lagpk2=lagpk0 syncbest2=sync flippk2=flip endif C We are most interested if snrx will be more than -30 dB. if(ppmax.gt.0.2938) then !Corresponds to snrx.gt.-30.0 if(sync.gt.syncbest) then ipk=i lagpk=lagpk0 syncbest=sync flippk=flip endif endif enddo C If we found nothing with snrx > -30 dB, take the best sync that *was* found. if(syncbest.lt.-10.) then ipk=ipk2 lagpk=lagpk2 syncbest=syncbest2 flippk=flippk2 endif C Generate frequency-tracking information if(NAFC.eq.1) then call afc65(s2,ipk,lagpk,flippk,ftrack) else do j=1,126 ftrack(j)=0. enddo endif C Peak up in frequency to fraction of channel base=0.25*(psavg(ipk-3)+psavg(ipk-2)+psavg(ipk+2)+psavg(ipk+3)) ! call peakup(psavg(ipk-1),psavg(ipk),psavg(ipk+1),dx) ! if(dx.lt.-1.0) dx=-1.0 ! if(dx.gt.1.0) dx=1.0 dx=0. dfx=(ipk+dx-i0)*df C Peak up in time, at best whole-channel frequency call xcor(s2,ipk,nsteps,nsym,lag1,lag2, + ccfblue,ccfmax,lagpk,flip,0.0) xlag=lagpk if(lagpk.gt.lag1 .and. lagpk.lt.lag2) then call peakup(ccfblue(lagpk-1),ccfmax,ccfblue(lagpk+1),dx2) xlag=lagpk+dx2 endif C Find rms of the CCF, without the main peak call slope(ccfblue(lag1),lag2-lag1+1,xlag-lag1+1.0) sq=0. nsq=0 do lag=lag1,lag2 if(abs(lag-xlag).gt.2.0) then sq=sq+ccfblue(lag)**2 nsq=nsq+1 endif enddo rms=sqrt(sq/nsq) snrsync=abs(ccfblue(lagpk))/rms - 1.1 !Empirical dt=2.0/11025.0 istart=xlag*nh dtx=istart*dt snrx=-99.0 ! ppmax=psavg(ipk)/base-1.0 ppmax=psavg(ipk)-1.0 C Plus 3 dB because sync tone is on half the time. (Don't understand C why an additional +2 dB is needed ...) if(ppmax.gt.0.0001) snrx=db(ppmax*df/2500.0) + 5.0 !### if(snrx.lt.-33.0) snrx=-33.0 C Compute width of sync tone to outermost -3 dB points call pctile(ccfred(ia-i0),tmp,ib-ia+1,45,base) jpk=ipk-i0 stest=base + 0.5*(ccfred(jpk)-base) ! -3 dB do i=-10,0 if(jpk+i.ge.-223) then if(ccfred(jpk+i).gt.stest) go to 30 endif enddo i=0 30 x1=i-1+(stest-ccfred(jpk+i-1))/(ccfred(jpk+i)-ccfred(jpk+i-1)) do i=10,0,-1 if(jpk+i.le.223) then if(ccfred(jpk+i).gt.stest) go to 32 endif enddo i=0 32 x2=i+1-(stest-ccfred(jpk+i+1))/(ccfred(jpk+i)-ccfred(jpk+i+1)) width=x2-x1 if(width.gt.1.2) width=sqrt(width**2 - 1.44) width=df*width width=max(0.0,min(99.0,width)) ic=600/df nn=1800/df nred=448 return end include 'afc65.f'